Optimal allocation model of port emergency resources based on the improved multi-objective particle swarm algorithm and TOPSIS method

The busy maritime traffic and occurrence of ship accidents have led to a growing recognition of the necessity to maritime emergency resources allocation. The port emergency resource allocation is of significant importance for the maritime safety. This paper presents an optimized allocation model for...

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Veröffentlicht in:Marine pollution bulletin Jg. 209; H. Pt B; S. 117214
Hauptverfasser: Guo, Jianqun, Jiang, Zhonglian, Ying, Jianglong, Feng, Xuejun, Zheng, Fengfan
Format: Journal Article
Sprache:Englisch
Veröffentlicht: England Elsevier Ltd 01.12.2024
Schlagworte:
Algorithms
case studies
China
dispersants
Emergency resource allocation
Entropy-weighted TOPSIS
environmental management
Improved particle swarm algorithm
marine pollution
Models, Theoretical
Multi-objective optimization
mutation
NSGA-II
oil spills
Petroleum Pollution
pollutants
Resource Allocation
sea transportation
Ships
China
NSGA-II
Multi-objective optimization
Entropy-weighted TOPSIS
Improved particle swarm algorithm
Emergency resource allocation
ISSN:0025-326X, 1879-3363, 1879-3363
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Zusammenfassung:The busy maritime traffic and occurrence of ship accidents have led to a growing recognition of the necessity to maritime emergency resources allocation. The port emergency resource allocation is of significant importance for the maritime safety. This paper presents an optimized allocation model for port emergency resources based on the improved multi-objective particle swarm optimization (IMOPSO). The model introduces the crowding distance and improves the external archive update strategy. The particle inertia weight is adjusted and a dynamic mutation operator is incorporated. The entropy-weighted technique for order preference by similarity to an ideal solution method is also employed to identify the optimal solution. A comprehensive comparison with MOPSO has been presented and discussed. Three metrics of generational distance (GD), spacing (SP) and delta indicator (Δ) were employed for performance evaluation. The results demonstrated that the proposed IMOPSO algorithm exhibited superior performance and robustness, with average values of GD = 0.0386, SP = 0.0023 and Δ = 0.6468 for ZDT test functions. The model efficacy is further validated by a case study of oil spill dispersant configuration at Zhanjiang Port, China. Seven alternative schemes have been obtained, among which the optimal scheme is selected by the entropy-weighted TOPSIS method. The overall cost is potentially to be reduced by approximately 33.03 %. The present study would provide a reference for the water pollutant control and environmental management in port waters. •An optimal allocation model based on IMOPSO and entropy weighted TOPSIS has been proposed for port emergency resources.•The MOPSO algorithm was further improved and its performance was quantitatively evaluated.•A case study of oil spill dispersant allocation was conducted at Zhanjiang Port and the model effectiveness was verified.•The optimal scheme determined by entropy-weighted TOPSIS would provide a guidance for marine environmental management.
Bibliographie:ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0025-326X
1879-3363
1879-3363
DOI:10.1016/j.marpolbul.2024.117214